tuberculosis infection?

Philana Ling Lin & team report on SIV/ART/TB models, finding antiretroviral treatment reduces pulmonary TB pathology, yet does not prevent extrapulmonary spread of TB.

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¹Department of Pediatrics, Children’s Hospital of Pittsburgh of the University of Pittsburgh Medical Center, Pittsburgh, Pennsylvania, USA.

²Center for Vaccine Research.

³Department of Microbiology and Molecular Genetics, and.

⁴Division of Laboratory Animal Research, University of Pittsburgh School of Medicine, Pittsburgh, Pennsylvania, USA.

Over the years, cell biology has built a detailed picture of how cells compartmentalize their internal functions. Central to this organization is the nucleus, which houses the genetic material and is separated from the cytoplasm by a robust nuclear envelope.

Traditionally, the nuclear membrane has been considered a strict barrier, maintaining nuclear integrity except during carefully controlled processes such as mitosis. As a result, the release of nuclear material has largely been associated with cellular damage or death.

However, recent work by a research team in Japan suggests that this view may be incomplete.

Since scientists first discovered that human immune cells could be modified to become cancer-fighting agents, they’ve been trying to engineer a cell that’s effective against solid tumors, which account for the vast majority of cancer cases. In a key advance in meeting this “holy grail challenge” in the field of cancer cell therapy, a team of Yale scientists led by geneticist Sidi Chen has revealed how immune cells can be “boosted” to target and eradicate solid tumors.

The field of cell therapy began to revolutionize cancer treatment several decades ago, when researchers pioneered the use of therapeutic cells. In this process, immune cells are removed from a patient, modified so that they can better fight cancer, and then reintroduced into the patient’s body.

Two major streams of this therapy exist: CAR-NK cell therapy, which uses a patient’s natural killer (NK) cells, and CAR-T cell therapy, which uses a patient’s T cells. In both cases, scientists genetically modify the cells to express Chimeric Antigen Receptor (CAR), a synthetic receptor that helps immune cells recognize proteins on cancer cells.

Although cancer is a common cause of death in domestic cats, little is known about the range of cancer genes in cat tumors, and how this range might compare with the oncogenome in people.

Now, researchers in Science have sequenced cancer genes in 493 samples from 13 different types of feline cancer and matched healthy control tissue, gaining a clearer picture of the cat oncogenome and comparing the genes to known cancer-causing mutations in humans.

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Cancer is a common cause of morbidity and mortality in domestic cats. Because the mutational landscape of domestic cat tumors remains uncharacterized, we performed targeted sequencing of 493 feline tumor–normal tissue pairs from 13 tumor types, focusing on the feline orthologs of ~1000 human cancer genes. TP53 was the most frequently mutated gene, and the most recurrent copy number alterations were loss of PTEN or FAS or gain of MYC. By identifying 31 driver genes, mutational signatures, viral sequences, and tumor-predisposing germline variants, our study provides insight into the domestic cat oncogenome. We demonstrate key similarities with the human oncogenome, confirming the cat as a valuable model for comparative studies, and identify potentially actionable mutations, aligning with a “One Medicine” approach.

Life’s genetic blueprint isn’t born in chaos—it’s built in 3D with precision from the very first moments.